Drop volume measuring apparatus



April 7, 1959 M. H. PELAvlN DROP VOLUME MEASURING APPARATUS Filed May 25, 1957/l IN V EN TOR. M'zan Pe/ay/fi ATTO RN EYS United States Patent O DROP VOLUME MEASURING APPARATUS Milton H. Pelavin, Forest Hills, N.Y., assignor to Technicon Chromatography Corporation, Chauncey, N.Y., a corporation of New York Application May 23, 1957, Serial No. 661,118v

16 Claims. (Cl. 141-130) The present invention relates to an apparatus for collecting predetermined volumes of liquids which issue in drop form from a source thereof.

The present invention is especially useful in an automatic fraction collection apparatus of the type shown in Patent No. 2,710,715 to George Gorham, dated June 14, 1955, and assigned to the assignee hereof. Said patent provides for obtaining predetermined quantities of liquid issuing in drop form from a chromatography column, or the like, and as shown therein, a predetermined quantity of the liquid is collected in each of a plurality of receptacles or containers. Said quantities may be determined, as provided in said patent, by counting the number of drops which issue from the chromatography column or by permitting each receptacle to receive drops for a predetermined period of time. Due to the fact that the drops issuing from the chromatography column may vary in volume, it is possible that there may be some diilerences in the volumes of the liquid collected in each of the receptacles whether the drop counting or the time counting arrangement is used. Under certain circumstances, it may be highly desirable, or even critical, that an extremely exact amount of liquid be collected in each of the receptacles. Consequently, it is an object of the present invention to provide a highly novel apparatus for collecting with great accuracy the same amount of a dropfalling liquid in each of a plurality of receptacles.

It is another object of the present invention to provide apparatus for measuring the volume of liquid collected in each of the receptacles of a fraction collector or the like, so as to provide an equal volume of liquid in each of the receptacles.

Another object is the provision of a highly novel and highly accurate device for collecting drops by volume rather than by counting the drops or on a time relationship.

The above and other objects, features and advantages of the present invention will be more fully understood from the following description considered in connection with the accompanying illustrative drawings.

In the drawings, which illustrate the best mode presently contemplated of carrying out the invention:

Fig. 1 is a combined block diagram and schematic representation of an apparatus pursuant to the present invention;

Fig. 1A is a more or less schematic view of part of the apparatus of Fig. l; and

Fig. 2 is a series of wave forms utilized in the explanation of said apparatus.

As here shown, the drop-volume measuring apparatus is utilized in connection with chromatography column 11 of conventional construction, provided with an outlet 12 through which liquid, in the form of drops, issues after passing through adsorbent substance 14 provided in the column. Provision is made for a light source 16 from which light passes through an aperture 18 provided in a suitable light shield 20, the light being formed into a 'ice beam 22 by said aperture. The beam of light 22 is focused by the lens 24 onto a photo-sensitive device or photo.

amplifier 30. Three conventional and well known delaycircuit stages 32, 34 and 36 which, for example 'and not by way of limitation, may be suitable multivibrators, are connected in parallel across the output of the amplifier 30, each of which stages is simultaneously triggered by an amplied pulse 28 at the output of the amplifier 30.

The delay circuits 32, 34 and 36 are similar in construction but each provides a dierent delay period. Delay circuit 32 provides a minimum delay period which is equal to the time T2 minus Tl, as shown in Fig. 2, the delay circuit 34 providing an intermediate delay'which is equal to time T4 minus Tl, and the delay circuit 36 providing a maximum delay which is equal to time T6 minus T1. The delayed pulse 38, at the output of delay circuit 32, is utilized to trigger a driven sweep circuit 40. The driven sweep circuit 40 is of conventional construction and, as is Well known to those skilled in the art, provides a voltage which is linear with respect to time. The output of circuit 40 is fed, as a horizontal sweep voltage, to the cathode ray camera tube 42. For each pulse 38 used to trigger the driven sweep circuit 40, there is provided one horizontal sweep in the camera tube 42.

In addition to the previously noted light source 16, there is provided an additional light source 44 whose rays pass through a diffusing glass 46 and through the aperture 48 in a light shield 50 to form the beam 52. The beam 52 passes through a collimating lens 54 and through a focusing lens 56 onto the face of a conventional camera tube 42. The beam of light 52 is positioned below the light beam 22 and also traverses the drop or fall path of the drops of liquid issuing from the outlet 12 so that each drop, as it passes through the position D2, intercepts the light beam 52. It will be apparent that whenever a drop falling from column 11 intercepts the light beam 52, the drop is imaged on the face of the camera tube 42. A conventional high voltage and low voltage power supply for the camera tube 42 is indicated by the referencenumeral 58. The delay introduced by the delay circuit 32 is timed in relation to the time required for the drop to pass from the position D1 to the position D2 thereof, so that the delayed pulse 38 triggers the sweep circuit 40 shortly after a drop in position D2 is imaged on the face of the camera tube 42.

The signal voltage developed by the imaging of the drop on the camera tube 42 is applied to a conventional time comparison circuit 60 which, as is well known to those skilled in the art, provides an output voltage proportional to the time duration of the output signal from the camera tube. More specifically, it will be understood that a substantially spherical drop at position D2 provides a two-dimensional image on the face of the camera tube 42, which produces a square wave pulse 62 at the output of the camera tube 42. Said pulse 62 has a time duration, for example of T3 minus T2, which is proportional to the width of the drop passing through position D2. The square or rectangular pulse 62 is fed to the time comparison circuit which, as previously indicated, is a conventional circuit and provides a voltage or signal output pulse 64 whose amplitude is proportional to the width or time duration of pulse 62.

The. output.signal pulse-64 of thetimecomparison circuit 60 is fed to a peak detector stage 66. The peak detector stage is of conventional and well known construction-and,- asis vwell'known to those skilled in the art, said stage-.providesfan outputisignal'which isA proportional to themaximumor. peak amplitude ofthe signal input appliedthereto. In other words, the output provided by the peak', detecto1:.6.6.` is, proportional yto vthe peak voltage of theginput signalpulsel 64,A the peak detector stage 66 beingchargedito the` pealcvalue of the input pulse 64, and

being provided with a time constant relationship such that-the stage -66 remains chargedas its peak value until the-stage v,is1discharged- Consequently, it will be apparent that the l'amplitude of the` charge in the peak detector stage isgproportionalto the, width of fthedrop since said charge amplitudeis.; proportional to` the peak amplitude of pulse 64,;and-,said latter-peakamplitudebeing proportional to thegwidth of the drop, asexplained above. The. wave form sindicates the charge yin the peak detector stage 66 resulting fionrtheinputsignal 64, thetermination of said wave-form, rasgat 69, indicating the discharge or recycling of stage 66,. ashereinafter explained-in detail.

Theoutputfofjthe peak detector 66 is utilized to energize a conventionalcubing amplier 7i), to provide a voltage output-from the latter which is equal to the cube oftheyoltagecharge inthe peak detector 66. However, due tothe time-constant-of the peak detector circuit, it is necessary..y to delayfthe application of the peak detector charge to thercubing amplifier until the peak detector is, charged` to the maximum voltage amplitude of its input signal. Intthis connection, provision is made for theJ secondldelay circuit34 at theoutput of the Aamplifier- 30, the delay circuit 34 introduces a delay of time-T4-Tl in thefeeding ofjafsignalfrorn the amplifier 30 to an input duration-y circuit r72 for` the cubing amplifier 70. The stage. 72 is `preferablyconstituted by a conventional oneshotmultivibratorwhichis triggered lby the signal pulse provided at .the l.output of delay circuit 34, and provides a pulsehavingfaqtime.duration oftime Fl`-T4, which is the same duration asthat illustrated for pulse 84.

Arelay coil 74;is,connected across the output of stage 72so that said relay will be energized for the time period T5-T4. The peak detector 66 is connected at the high voltage side thereof to the movable contact 76 of said coil, theassociatedstationary contact 78 being connected to the high voltage side of the cubing ampliiier 70 through the line 80. The peak detector is connected at the other side thereof throughvthe line 82 to the other side of the cubing amplifier 70. Consequently, it will be apparent thatruponenergization ofthe relay coil 74 by the output pulseoftheduriation stage 7,2-which,V as previously indicated, has aV-.widthcorresponding to T5 minus T4, and a delay: correspondingfto T4 minus Tl, the engagement of the contacts 76and 78 `will be effected for the period T5- T 4 toy apply the output of the peak detector 66, during said period, vtothe'cubing amplifier 70. As previously indicated, the cubing amplier 70 is of conventional construcfy tion andprovides lat its output the cubedpulse 84 which has as tiirlefdurationofgtime T5 minus T4, which as stated above, fisthe-period duringwhich the relay 74 is energized by'theloutput ofthe duration stage 72.

Asv previously indicated, the drops, falling from the outlet 12 ofthe column 10 into the receptacle 86, are

substantially spherical in form and, since the volume of- Thelcubing'almpliiierIoutput furnishes the/signal voltage.

for a conventional balancinglservo system, generally indicated by the reference numeral 88. As here shown,

the .Y cubing.,l amplifier .output isdeveloped across the rer,

sistors and 92 which, with a slide wire potentiometer 94 connected in parallel therewith, form components of a conventional null-type balancing system. The potential difference appearing between the junction 96, between the resistors 90 and 92, andthe tap 98, of the slide wire potentiometer 94, is applied to a conventional servo arnplirier 1ML The output.of the` latter is applied, through the terminals 10k-10,2, to one phase winding of a conventional two phase V.motor 104, the othernphase winding of which is energized from a suitable A.C. source connected to the terminals 106--106 thereof. The shaft 168 of theservo motor 104 is coupled to the slide arm 98 through a gear reduction trainllltl and, as is well understood by those skilled in the art, the motor 104 continues to operate until the slide arm 98 reaches a position of balance along the slide wire 94, at which there is no potential diierence between .the .junction 96 and thevoltage at ,the tapforfarm 98.

The motor shaft 108 is, coupled througha uni-directional coupler=112toaconventional counting device 114. Said counter 114V is larevolution counter of the vpredetermining typewhereinthe revolutions of the motor shaft 108 are successivelyicounted, the counts resulting from each pulse outputoffthe. cubing amplifier 70y being added to the counts .resulting from aprior pulse output thereof. Inthis connection, it vwill berunderstood that the counter 11A-counts inonly1 one direction. of rotation of the shaft 11S, of the; servo motor, ltlddue to the uni-directional coupler 112. As is,custornary-in the described type of counting device V.11.4, thelatter has provision to complete a lcircuit orcloseapair of contactswhen the successiver counts recordedtheteon reach a predetermined total; Forexample, the..cpunter mayffbeprovided witha normally tie-energizedrelay-,1coilVlISyhaving a pair of normally open `contacts 116-118, kand-it willbe understood that, upon the counter114reahing apredetermined total, the relay llsvisenergized toclose said contacts. From the foregoing, it will bereadily vapparent that acubed voltage, proportional tothe width of each pulse 62 provided at the output of the camera tube 42, is recorded as a count on the co-unterlll, ythe,number of revolutions or counts of the latter foreach pulsebeing proportional to the cube or" the pulse and, consequently, to the volume of the drop whose-image providedthe corresponding pulse.

As previouslyv indicated, the peak detector stage 66 retains a chargerepresentativeof each drop passing the camera tubeuntil said peak detector stage is relieved of the charge. Furthermore, in order` to effect` the cledrop,haspassedthroughthez position D2 and before the following droppasses throughV the position D1. In thisl connection, itwillbe, notehthat drops issuefrom the outlet 12 vof'the.chromatography.column 10 at relatively.

longtime intervals, for example-and not. by way of limitation, there may be. intervalsr of two or three minutes between drops.

In' order. to recycle theV apparatus, the peak detector 66 is shorted, at the outlet side thereof, after each counting operation. In this contraction as previously.v indicated, the original pulse 28 developed byz thephoto-sensitive device 26 .isalso applied tothe third delay. staget. The delayr provided, byfthelstage36 is equal to the time T6 minus the time T11; A relayl coil 128is connected'across the output ofthe delay-.stage 36. The relay 128 has a moyablecontact 130.connected to the lead S2 and a stationary contact 132; which is connected to the movable contact l 76 ofthe relay.- 74.

Tha-closing of the contacts76 and:7tiA initiates apulse signal applied by the peak detector 66 to the cubing amplifier 70, the amplitude of said pulse being proportional to the width of the drop, as previously explained. A recycling pulse is provided by the third delay circuit 36 which provides an output pulse, having a delay period of T6 minus T1, to the relay 128 to close the contacts 130-132 thereof for shorting the peak detector 66, as indicated at 69 on the wave form 68. In addition to shorting the output of the peak detector 66, the closed contacts short the input to the cubing amplifier 70, causing output to the servo amplier to be cut off to unbalance the bridge constituted by resistors 90, 92 and 98, and the servo motor 104 operates in the opposite direction to return to its zero position. However, due to the unidirectional coupler 112, said opposite rotation of the shaft 108 does not result in a count being recorded on the counter 114.

The closing of the relay contacts 116 and 118 is utilized to remove the iilled container 86, which now 'has a predetermined volume of the liquid, from under the outlet 12 and to replace the container 86 with another container preferably utilizing the fraction collector apparatus disclosed in the previously identified Patent No. 2,710,715, and generally indicated herein by the reference numeral 156. More speciiically, in said prior patent, provision is made to periodically energize a rack moving motor 288 under the controlv of a counting device, the schematic wiring diagram of which is indicated by the reference numeral 592 in Fig. 31 of said patent. As illustrated in Fig. 1A the rack 289 is rotated intermittently by the engagement .of pin 291 with the toothed edge 293 of the rack as described in said Patent No. 2,710,715. Pin 291 is rotated by the shaft 295 of motor 2188 through the gearingl 297. In accordance with the present invention the drop volume measuring apparatus is utilized in lieu of the drop counting device 592 of said patent to provide a predetermined volume of liquid in each of the containers 86. The circuitry-utilized in connecting the drop volume measuring apparatus 10 of the present invention to the main control unit 562 of ,the automatic fraction collection apparatus, as shown in Fig. 3l, includes the relay coil 134 one end of which is Aconnected to contact 118 through an RC network constituted by the capacitor 136 and a resistor 138. The other end of the relay 134 is grounded. When the counter 114 reaches a predetermined count, as explained above, the contacts 116 and 118 close and the RC network 136- 136 is charged by the potential source to provide a positive potential for energizing the relay 134. The latter is provided with a movable contact 140 and a companion stationary contact 142. The movable contact 140 is connected to one end of a relay coil 144 and to a stationary contact 146 of said coil.

The terminal'strip 598 of said prior patent is illustrated by the similarly numbered terminal strip herein and the various terminals shown herein and parts extending to the right of said terminals represent the correspondingly or similarly numbered parts or components of the fraction collector apparatus 156 of said prior patent. The stationary contact 142 is connected to the terminal 608 of said terminal strip 598 and the other end of the relay 144 is connected through the lead 148 to the terminal 606. The movable contact 150 of said relay 144, companion to the stationary contact 146 thereof, is connected to the terminal 612. A second movable contact 152 of said relay is connected to the terminal 614 and a stationary Contact 154, companion Yto said contact 152, is connected to the terminal 608. With thecontrol switch 580 of the automatic fraction collection apparatus `156 in -the illustrated condition thereof to provide an equally measured volume of liquid in each container 86, the contact 142 of relay 134 is connected through the ,terminal 608 `and closed switch section .508B to one power terminal 564, the relay 144 being connected through the line 148, the terminal 606 and the closed switch section 508A to the other power terminal 572. The unit motor 288, which is 6 intermittently operated to intermittently rotate the eolitainer holding vrack of the automatic fraction collection apparatus 156, is connected between the terminal 614 and the power terminal 572. vThe reset switch 364, of the automatic fraction collection apparatus, is connected between the terminals 608 and 612.

Assuming now that a predetermined count has been reached by the counter 114, the contacts 116, 118 thereof will close to charge the RC network 136-138 to energize the relay 134. This closes the contacts 140-'142 thereof and completes a circuit ybetween one side of the relay 144 and the power terminal 564, the other side of relay 144 being connected to the power terminal 572. Energization of the relay 144 results in the closing of the contacts 146-150 .thereof to provide a holding circuit for retaining said'relay 144 in energized condition after the de-energization of the relay 134 due to the decrease in charging current through capacitor 136. It will be noted that the holding circuit for the relay 144 includes the closed reset switch 364. Energization of the relay 144 also closes its contacts 152- 154 to complete the energizing circuit for 'the motor 288 through the contacts 152- 154 to the power terminal 564. The motor now operates to rotate its rack to move the iilled receptacle or container 86 from beneath the outlet 12 and to replace the iilled container with an empty container positioned under said outlet, as fully illustrated and described in said patent. Shortly before the motor has completed its movement, the reset switch 364 is operated by a cam driven bythe motor, as fully illustrated and described in said patent, to open the switch 364 for interrupting the holding circuit of the relay 144 to de-energize the latter andA to open the paired contacts thereof.

Consequently, `it will be readily apparent that the apparatus 10 may be utilized to provide an equally measured volume of liquid in'each container 86 of the fraction collector 156, to provide a highly accurate equal volume or fraction of the liquid in each receptacle or container of the fraction collector.

While I have shown and described the preferred embodiments of my invention, it will be understood that various changes may be made in the idea or principles of the invention within the scope of the appended claims.

Having thus described my invention, what I claim and desire to secure by Letters Patent is:

1. Apparatus for measuring the volume of one or more falling drops of liquid comprising means for providing a falling drop of the liquid, means operable in response to the fall of the drop in relation thereto to provide a voltage proportional to the width of a drop, means to cube said voltage, and means to measure said cubed voltage whereby to provide a measurement proportional to said volume.

2. Apparatus for measuring the volume of a drop of liquid comprising means to provide a voltage proportional to the width of said drop, means for directing a series of liquid drops in succession in operative relation to said voltage providing means for controlling the operationof the latter for generating the voltage, means to cube said voltage, and means to measure said cubed voltage whereby to provide a measurement proportional to said volume, said measuring means comprising means to provide a count proportional to said cubed voltage, means to receive one or more drops of the liquid, and means operable under the controlof said measuring means for controlling the volume of liquid delivered to said receiving means.

3. Apparatus for measuring the volume of one or more drops of liquid comprising means to provide a voltage proportional to the width of a drop, means for directing a series of liquid drops in succession in operative relation to said voltage providing means for controlling the operation of the latter for generating the voltage, means to cube said voltage, and means to measure said cubed voltage whereby to provide a measurement proportional to said volume, said measuring means comprising a servo system l?, reSPgaSYe tgsarl; Called' vgltaae, and, @munter device.. @Ramble by Said, SerfvQ systmtjiaseas; tdreivou r more drops of the liquidgand means operablerunder the control ofA said measuringfrneans for controlling the Yvolume of liquid delivered tosaidfmeasuring means'.

4. Apparatus for measuring theuvvolume of one or more drops of liquid comprising means. to provide va voltage proportional to the width of a drop, means for directing a series of liquid drops in succession inoperative relation to `said voltage providing means for controlling the opera tion of the latter for generating thenvoltage, means to cube said voltage, and means to, measure said cubed voltage whereby to provide a measurement proportional to said volume, saidmeasuring means comprising a servo system responsive to said cubed voltage, av cumulative counter device operable by said servo system, a normally, deenefsized, WOIKfCOIitfAQI-Cruia and means. ,fof "erif'gizin'g said circuit in response ,toa predetermined cumulative count attained by saidcounter device. v

5. Apparatus for measuring the volume of a drop of liquid comprising means to provide avvoltage proportional to the volume of said drop.,y saidmeans comprising opticalelectrical means and means for imaging said drop on said optical-electrical means for generating Asaid voltage, and means operable under the control of said voltageto provide a measurement proportional to said volume.

6. Apparatusv for measuring the volume ofi avdrop of liquid comprising, camera tube means, means to image the drop on saidI camera tube means'to provide an output signal from said camera tubefmeans proportional to thevwidth ofthe drop image, means 'to cube saidoutput signal to providea signalj whiehis'proportional toV the 4volurne o f the imaged dr'op, and-means to e'tect'a measurementof saidcubed signal.:y i i' p 7. Apparatus for measuring the volume of a drop of liquid Comprising. Gamefacts@ tareas, means fo'image the drop on said camera tube means to provide an output pulse from said camera tubeimeans having a timeduration proportional to the width` of the drop image, a time comparison circuit at the output of said camera tube and operable to provide a pulse having a magnitude proportional to the -width of said first mentioned pulse, means to provide an output voltage having a magnitude which is the cube of the magnitudenof` said second mentioned pulse, and means to etect ameasurement of said last mentioned output voltage. l l 'i i A 8. Apparatus for measuring the volume of a drop of` liquid-comprising, camera tube means, means to image the drop on said camera tube means to provide an output pulse from saidpcamera tube means having a time-duration proportional' to the width of thedrop image, a time comparison circuit at'the output ofi-saidcamera tube and operable to provide a pulserhaving a magnitude proportional to the width'of said first mentioned pulse, a peak detector circuit atthc 'output ofsaid time comparison circuit to provide a voltage output at the peak value of said second mentioned pulse, and means to effect a measurement of said last mentioned output voltage.I

V9. Apparatus for measuring the volume of a drop of liquid as the drop falls through space, said apparatus a said camera tube after interception ofthe 'light beam, said` sweep circuit being'energized substantially when the drop .is imaged on said "camera tube' to provide at the Voutput of the latter a pulsehavinga timc'tdur'ation proportional tothe width ofthe drop image, 'a time` comparison circuit at the outputof saidcamera tube and operable to provide a pulse having a magnitude proportonal'to the width ofl said 'rst mentioned pulse, means to provide. an output-l voltage ltiavingamagnitude which is the cube ofthe magnitude of said second mentioned pulse, and means to eiect a measurement of said last mentioned output voltage.

l0. Apparatus for measuring the volume of a drop of liquid as the drop falls through space, said apparatus a camera tube, a normally de-energized driven-sweep circuit operable Vwhen energized to provide a single sweep on the face of said camera tube, photo-electric means in circuit with said sweep circuit through a delay circuit interposed therebetween, means to focus a light beam on said photo-electric device fory interception by a falling drop to energize said sweep circuit after a delay predetermined by said delay circuit, means to image the falling drop on said camera tube after interception of the light beam, said sweep circuit being energized substantially when the drop is imaged on said 'camera tube to provide at the output of the* latter a pulse having a time duration proportional to width ofthe drop image, a time comparison circuit at the output of said camera tube and operable to provide a pulse having a magnitudeproportional to the width of said first mentioned pulse, aV peak detector circuit at the output of said time comparison circuit to provide a voltage out-put at the peak value of said second mentioned pulse, a cubing amplier circuit at the output of said peak detector circuit, said cubing amplifier being normally disconnected from said peak'detector'circuit, means including a second delay circuit energized by said photo-electric means and providing a delay greater than said first mentioned delay to connect said cubing amplier to said peak detector for a predetermined period after the latter is charged tothe peak value offsaid'secondmentioned pulse, andmeans tq eiect a measurementofe the output voltage of saidv cubing ampliler circuit.

1l. Apparatus as settorth in claim 10, further characterized in that provision is made for means including a third delay circuit energized by said photo-electric device and operable after a'delay period greater than said seconddelay period to discharge'said peak detector circuit.

l2. Apparatus as set forth in claim 10, further characterized in that said measuring means comprises a null type measuring circuit which includes a servo-motor and a counter having a uni-directional coupling with said motor, and provision is madel for means including a third delay circuit energized by saidv photo-electric device and operable after a delay period greater than said second delay period to discharge said peak detector circuit and to zero said motor.

13. Apparatus of the character described, comprising a device provided with a material discharge outlet, container-supporting means mounted for movement in relation to said outlet and constructedl and arranged to carry a plurality. of containers yin spaced relation to position thecontainers to receive material discharged from said outlet, means for moving said.container-supporting means intermittently to present said containers in succession to saidreceiving position, and material volume-measuring means for determining the rest period of said containersupporting means between the intermittent movements thereof, said'material being discharged in drops and said volume-measuring means operable to measure the volume of each drop and to accumulate said measurements to provide a count of the material discharged into the container.` Y Y 14. Apparatus of the character described, comprising a device provided with a material discharge outlet, container-supporting meansrnounted-for movement in relation to said outlet and constructed and arranged to carry a plurality of containers in spaced 4relation to position the containers to receive materialy discharged from said outlet, means for moving said container-supporting means intermittently to present said containers in succession to said receiving position, and materialvolume-measuring means tory determining the rest period of said container-supporting' means between the intermittent-movements thereof,

said material Volume measuring means comprising means to measure directly the volume of the material discharged from said outlet into each container.

15. Apparatus of the character described, comprising a device provided with a material discharge outlet, container-supporting means mounted for movement in relation to said outlet and constructed and arranged to carry a plurality of containers in spaced relation to position the containers to receive material discharged from said outlet, means for moving said container-supporting means intermittently to present said containers in succession to said receiving position, and material volume-measuring means for determining the rest period of said container-supporting means between the intermittent movements thereof, said material being discharged in drops and said volumemeasuring means operable to measure the volume of each drop and to accumulate said measurements to provide a count of the material discharged into each container, and switch means in circuit with said volume-measuring means and operable in response to the receipt of a predetermined volume of material in the container in said position to energize said moving means to terminate said rest period.

16. Apparatus of the character described, comprising a device provided With a material discharge outlet, container-supporting means mounted for movement in relation to said outlet and constructed and arranged to carry a plurality of containers in spaced relation to position the containers to receive material discharged from said outlet, means for moving said container-supporting means intermittently to present said containers in succession to said receiving position, and material volume-measuring means for determining the rest period of said containersupporting means between the intermittent movements thereof, said material volume measuring means comprising means to measure the volume of each drop of material discharged from said outlet, and means to add the drop-volume measurements to provide ya predetermined total drop-volume measurement for each container.

References Cited in the le of this patent UNITED STATES PATENTS 2,710,715 Gorham .Tune 14, 1955 2,750,110 Och June 12, 1956 2,809,784 Brook Oct. 15, 1957 

